Elastomer porous material and method of producing the same

- Synztec Co, Ltd.

In the elastomer porous material of the invention, when cells in a first observation region of a first cross section are observed at a certain magnification, cells having an aspect ratio a/b, wherein a represents the maximum diameter of each cell and b represents the length of the minor axis of that cell as measured in a direction orthogonal thereto, of 1.3 or less account for 70% or more of all cells in the first observation region, and, when cells in a second observation region of a second cross section orthogonal to the first cross section are observed at a certain magnification, cells having an aspect ratio a/b, wherein a represents the maximum diameter of each cell and b represents the length of the minor axis of that cell as measured in a direction orthogonal thereto, of 1.3 or less account for 70% or more of all cells in the second observation region.

Skip to: Description  ·  Claims  ·  References Cited  · Patent History  ·  Patent History
Description

This application is a 35 U.S.C. 371 national stage of International application PCT/JP2008/071825 filed on Dec. 1, 2008; which claimed priority to Japan application 2007-311799 filed on Nov. 30, 2007. The entire contents of each of the above-identified applications are hereby incorporated by reference.

FIELD OF THE INVENTION

The invention relates to an elastomer porous material such as a silicone elastomer porous material, and to a method for producing the elastomer porous material. More particularly, the present invention relates to an elastomer porous material having substantially true spherical cells, and to a method for producing the elastomer porous material.

BACKGROUND OF THE INVENTION

Silicone elastomer porous materials are used in a variety of fields; for example, in components of image-forming devices (e.g., copying machines and laser printers), including a developing roller, a toner-feeding roller, a transfer roller, and a cleaning roller. Also, silicone elastomer porous materials are used in paper-sheet-feeding rollers of copying machines, various types of printers, and plotters, as well as in fixing components (e.g., a fixing roller and a pressure roller).

Hitherto, porous materials have generally been produced by means of foaming action. In a technique for causing foaming action, a chemical foaming agent, a gas, or water is used as a foaming agent.

In most cases of production of a silicone elastomer porous material, such a foaming agent is also used. However, in conventional methods for producing such a silicone elastomer porous material, curing of silicone rubber and foaming are performed in parallel, and thus the resultant porous material has cells (pores) which are not uniform in size; i.e., their sizes considerably differ from one cell to another. In addition, difficulty is encountered in forming spherical cells having a small size.

In view of the foregoing, Patent Document 1 discloses a method for producing a silicone elastomer porous material by freezing a room-temperature-curable organopolysiloxane emulsion containing, for example, an organopolysiloxane having a silanol group, a specific cross-linking agent, a curing catalyst, and an emulsifier, and drying the frozen emulsion by sublimation of water without thawing. However, this method also encounters difficulty in producing a porous material having small cells of uniform size.

When a silicone elastomer porous material produced by use of a foaming agent is used in a fixing roller, since the porous material has large cells of non-uniform size, the fixing roller poses problems in that it exhibits inconsistent form upon heating, and, when torque is applied to the fixing roller, the roller is likely to break due to failure to achieve uniform distribution of the torque. When a porous material having large-sized cells is used in, for example, a pressure roller, the contours of the cells may appear on a formed image. Thus, demand has arisen for a silicone elastomer porous material having small cells of uniform size.

The present applicant previously applied for a patent on a closed-cell silicone elastomer porous material which is produced essentially from a water-in-oil emulsion containing water and a liquid silicone rubber material that forms a silicone elastomer through curing (see Patent Document 2).

However, on the basis of subsequent studies, the present inventors have found that the thus-produced silicone elastomer porous material has cells attributed to the water-in-oil emulsion, as well as cells attributed to bubbles entrained upon preparation of the water-in-oil emulsion, and thus the porous material is unsatisfactory in terms of properties (in particular, durability) required of a silicone elastomer porous material.

  • Patent Document 1: Japanese Patent Application Laid-Open (kokai) No. H06-287348
  • Patent Document 2: Japanese Patent Application Laid-Open (kokai) No. 2005-206784

DISCLOSURE OF THE INVENTION SUMMARY OF THE INVENTION

In view of the foregoing, an object of the present invention is to provide an elastomer porous material which is produced from an emulsion, and which has substantially true spherical cells. Another object of the present invention is to provide a method for producing the elastomer porous material.

In a first mode of the present invention attaining the aforementioned objects, there is provided an elastomer porous material, characterized in that, when cells in a first observation region of a first cross section are observed at a certain magnification, cells having an aspect ratio a/b, wherein a represents the length of the major axis of the perimeter of each cell (hereinafter referred to as “maximum diameter”) and b represents the length of the minor axis of that cell as measured in a direction orthogonal thereto, of 1.3 or less account for 70% or more of all cells in the first observation region, and, when cells in a second observation region of a second cross section orthogonal to the first cross section are observed at a certain magnification, cells having an aspect ratio a/b, wherein a represents the maximum diameter of each cell and b represents the length of the minor axis of that cell as measured in a direction orthogonal thereto, of 1.3 or less account for 70% or more of all cells in the second observation region.

A second mode of the present invention is drawn to a specific embodiment of the elastomer porous material as described above, which is produced from an emulsion composition comprising, as a continuous phase, a liquid rubber material which forms an elastomer through curing.

A third mode of the present invention is drawn to a specific embodiment of the elastomer porous material as described above, wherein the liquid rubber material is a liquid silicone rubber material.

A fourth mode of the present invention is drawn to a specific embodiment of the elastomer porous material as described above, wherein, in the first or second observation region, cells having a diameter of 50 μm or less account for 50% or more of all cells.

A fifth mode of the present invention is drawn to a specific embodiment of the elastomer porous material as described above, wherein, in each of the first and second observation regions, cells having a shape factor SF1, which indicates the roundness of a circle and is represented by the following formula:

SF 1 = π a 2 4 A × 100 [ F1 ]
(wherein a represents the length of major axis of each cell, and A represents the area thereof), of 150 or less account for 80% or more of all cells.

A sixth mode of the present invention is drawn to a specific embodiment of the elastomer porous material as described above, wherein, in the first observation region, cells having a shape factor SF2, which indicates the remoteness from complete roundness and is represented by the following formula:

SF 2 = P 2 4 π A × 100 [ F2 ]
(wherein A represents the area of each cell, and P represents the perimeter length thereof), of 130 or less account for 80% or more of all cells.

A seventh mode of the present invention is drawn to a specific embodiment of the elastomer porous material as described above, wherein, in the second observation region, cells having a shape factor SF2, which indicates the remoteness from complete roundness and is represented by the following formula:

SF 2 = P 2 4 π A × 100 [ F3 ]
(wherein A represents the area of each cell, and P represents the perimeter length thereof), of 130 or less account for 80% or more of all cells.

An eighth mode of the present invention is drawn to a specific embodiment of the elastomer porous material as described above, which exhibits a porosity of 30% or more and has 200 or more cells per mm2 as observed in a cross section.

In a ninth mode of the present invention, there is provided a roll member characterized by comprising the elastomer porous material as recited in any of the first to eighth modes.

In a tenth mode of the present invention, there is provided a fixing member characterized by comprising the elastomer porous material as recited in any of the first to eighth modes.

In an eleventh mode of the present invention, there is provided a method for producing an elastomer porous material, characterized in that the method comprises preparing, under reduced pressure, an emulsion composition comprising, as a continuous phase, a liquid rubber material which forms an elastomer through curing; and curing the emulsion composition while removing a dispersion phase, to thereby produce an elastomer porous material.

A twelfth mode of the present invention is drawn to a specific embodiment of the elastomer porous material production method as described above, wherein the liquid rubber material is a liquid silicone rubber material.

A thirteenth mode of the present invention is drawn to a specific embodiment of the elastomer porous material production method as described above, wherein the emulsion composition is a water-in-oil emulsion composition comprising a liquid silicone rubber material, a silicone oil material having interfacial activity, and water.

A fourteenth mode of the present invention is drawn to a specific embodiment of the elastomer porous material production method as described above, which produces an elastomer porous material wherein, when cells in a first observation region of a first cross section are observed at a certain magnification, cells having an aspect ratio a/b, wherein a represents the maximum diameter of each cell and b represents the length of the minor axis of that cell as measured in a direction orthogonal thereto, of 1.3 or less account for 70% or more of all cells in the first observation region, and, when cells in a second observation region of a second cross section orthogonal to the first cross section are observed at a certain magnification, cells having an aspect ratio a/b, wherein a represents the maximum diameter of each cell and b represents the length of the minor axis of that cell as measured in a direction orthogonal thereto, of 1.3 or less account for 70% or more of all cells in the second observation region.

A fifteenth mode of the present invention is drawn to a specific embodiment of the elastomer porous material production method as described above, which produces an elastomer porous material wherein, in the first or second observation region, cells having a diameter of 50 μm or less account for 50% or more of all cells.

A sixteenth mode of the present invention is drawn to a specific embodiment of the elastomer porous material production method as described above, which produces an elastomer porous material wherein, in each of the first and second observation regions, cells having a shape factor SF1, which indicates the roundness of a circle and is represented by the following formula:

SF 1 = π a 2 4 A × 100 [ F4 ]
(wherein a represents the length of major axis of each cell, and A represents the area thereof), of 150 or less account for 80% or more of all cells.

A seventeenth mode of the present invention is drawn to a specific embodiment of the elastomer porous material production method as described above, which produces an elastomer porous material wherein, in the first observation region, cells having a shape factor SF2, which indicates the remoteness from complete roundness and is represented by the following formula:

SF 2 = P 2 4 π A × 100 [ F5 ]
(wherein A represents the area of each cell, and P represents the perimeter length thereof), of 130 or less account for 80% or more of all cells.

An eighteenth mode of the present invention is drawn to a specific embodiment of the elastomer porous material production method as described above, which produces an elastomer porous material wherein, in the second observation region, cells having a shape factor SF2, which indicates the remoteness from complete roundness and is represented by the following formula:

SF 2 = P 2 4 π A × 100 [ F6 ]
(wherein A represents the area each cell, and P represents the perimeter length thereof), of 130 or less account for 80% or more of all cells.

EFFECTS OF THE INVENTION

According to the present invention, there can be provided an elastomer porous material having substantially true spherical and fine cells and exhibiting excellent durability.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 shows an SEM photograph of a radial cross section and a first observation region in Example 1.

FIG. 2 shows an SEM photograph of a longitudinal cross section and a second observation region in Example 1.

FIG. 3 shows an SEM photograph of a radial cross section and a first observation region in Example 2.

FIG. 4 shows an SEM photograph of a longitudinal cross section and a second observation region in Example 2.

FIG. 5 shows an SEM photograph of a radial cross section and a first observation region in Example 3.

FIG. 6 shows an SEM photograph of a longitudinal cross section and a second observation region in Example 3.

FIG. 7 shows an SEM photograph of a radial cross section and a first observation region in Comparative Example 1.

FIG. 8 shows an SEM photograph of a longitudinal cross section and a second observation region in Comparative Example 1.

FIG. 9 shows an SEM photograph of a radial cross section and a first observation region in Comparative Example 2.

FIG. 10 shows an SEM photograph of a longitudinal cross section and a second observation region in Comparative Example 2.

FIG. 11 shows an SEM photograph of a radial cross section and a first observation region in Comparative Example 3.

FIG. 12 shows an SEM photograph of a longitudinal cross section and a second observation region in Comparative Example 3

FIG. 13 is a graph showing SF1 distribution in the first observation region in Example 1.

FIG. 14 is a graph showing SF1 distribution in the second observation region in Example 1.

FIG. 15 is a graph showing SF1 distribution in the first observation region in Example 2.

FIG. 16 is a graph showing SF1 distribution in the second observation region in Example 2.

FIG. 17 is a graph showing SF1 distribution in the first observation region in Example 3.

FIG. 18 is a graph showing SF1 distribution in the second observation region in Example 3.

FIG. 19 is a graph showing SF1 distribution in the first observation region in Comparative Example 1.

FIG. 20 is a graph showing SF1 distribution in the second observation region in Comparative Example 1.

FIG. 21 is a graph showing SF1 distribution in the first observation region in Comparative Example 2.

FIG. 22 is a graph showing SF1 distribution in the second observation region in Comparative Example 2.

FIG. 23 is a graph showing SF1 distribution in the first observation region in Comparative Example 3.

FIG. 24 is a graph showing SF1 distribution in the second observation region in Comparative Example 3.

FIG. 25 is a graph showing SF2 distribution in the first observation region in Example 1.

FIG. 26 is a graph showing SF2 distribution in the second observation region in Example 1.

FIG. 27 is a graph showing SF2 distribution in the first observation region in Example 2.

FIG. 28 is a graph showing SF2 distribution in the second observation region in Example 2.

FIG. 29 is a graph showing SF2 distribution in the first observation region in Example 3.

FIG. 30 is a graph showing SF2 distribution in the second observation region in Example 3.

FIG. 31 is a graph showing SF2 distribution in the first observation region in Comparative Example 1.

FIG. 32 is a graph showing SF2 distribution in the second observation region in Comparative Example 1.

FIG. 33 is a graph showing SF2 distribution in the first observation region in Comparative Example 2.

FIG. 34 is a graph showing SF2 distribution in the second observation in Comparative Example 2.

FIG. 35 is a graph showing SF2 distribution in the first observation region in Comparative Example 3.

FIG. 36 is a graph showing SF2 distribution in the second observation region in Comparative Example 3.

FIG. 37 is a schematic representation of the internal structure of a belt fixing apparatus employed in Test Example 3.

DESCRIPTION OF REFERENCE NUMERALS

  • 10: Belt fixing apparatus
  • 21: Fixing roller
  • 22: Pressure roller
  • 23: Heating roller
  • 24: Heat source
  • 25: Fixing belt

DETAILED DESCRIPTION OF THE INVENTION

The elastomer porous material of the present invention is formed of an elastomer matrix and has numerous fine cells of substantially true spherical form distributed in the matrix.

Examples of the elastomer forming the matrix include silicone, urethane, chloroprene, ethylene-propylene copolymer (EPM), ethylene-propylene terpolymer (EPDM), styrene rubber (SBR), nitrile rubber (NBR), polyester elastomer, polyether elastomer, polyolefin elastomer, and epichlorohydrin rubber.

The elastomer porous material of the present invention is produced from an emulsion composition containing, as a continuous phase, a liquid rubber material which forms an elastomer. Specifically, the elastomer porous material is produced through the following procedure: the liquid rubber material (i.e., the continuous phase of the emulsion composition) is cured while the composition is maintained in an emulsion state, to thereby form an elastomer matrix, and subsequently the dispersion phase is removed to form cells. The thus-formed cells present in the porous material are substantially independent of one another. When the emulsion composition is prepared under reduced pressure so as to remove bubbles contained in the composition, the resultant porous material has only cells formed by removal of the dispersion phase; i.e., the porous material has substantially true spherical cells.

More specifically, the elastomer porous material having only substantially true spherical cells is produced by removing cells attributed to bubbles entrained in the emulsion composition. Most of the cells attributed to bubbles entrained in the emulsion composition have a diameter falling outside the range of the normal distribution of that of cells attributed to the emulsion (e.g., a diameter of 50 to 60 μm). When the cells attributed to such bubbles are precisely observed, the cells are not in a true spherical form, but in a considerably flattened form. The present inventors have found that such considerable flattening of the cells, which may occur upon curing of the elastomer, causes deterioration of properties (in particular, durability) of the elastomer porous material.

The elastomer porous material of the present invention can be confirmed to have only substantially true spherical cells by observing not one certain cross section, but two orthogonal cross sections. Cells confirmed to be in a true circular form in the two orthogonal cross sections are also in a true circular form in another cross section orthogonal to these two cross sections.

In the present invention, cells observed in an observation cross section are confirmed to have a true circular form by determining that cells having an aspect ratio a/b, wherein a represents the maximum diameter of each cell and b represents the length of the minor axis of that cell as measured in a direction orthogonal thereto, of 1.3 or less account for 70% or more of all cells in the observation region.

Specifically, in the elastomer porous material of the present invention, when cells in a first observation region of a first cross section are observed at a certain magnification, cells having an aspect ratio a/b, wherein a represents the maximum diameter of each cell and b represents the length of the minor axis of that cell as measured in a direction orthogonal thereto, of 1.3 or less account for 70% or more of all cells in the first observation region, and, when cells in a second observation region of a second cross section orthogonal to the first cross section are observed at a certain magnification, cells having an aspect ratio a/b, wherein a represents the maximum diameter of each cell and b represents the length of the minor axis of that cell as measured in a direction orthogonal thereto, of 1.3 or less account for 70% or more of all cells in the second observation region.

For determination of the aspect ratio, the two orthogonal cross sections are observed under an SEM, and each of the first and second observation regions is determined so that, for example, 40 to 80 cells are observed in the region. The aspect ratio a/b is determined by measuring the length of major axis a of each cell representing its maximum diameter of each cell and the length b of the miner axis of that cell in a direction orthogonal thereto. Whether or not the cells in each of the observation regions satisfy the aforementioned requirements are determined on the basis of the thus-obtained aspect ratio a/b.

Measurement of the length of major axis a and the length b of each cell may be carried out through analysis of SEM image data input into a computer by means of, for example, image analysis software.

Each of the first and second observation regions may be determined so that, for example, about 40 to about 80 cells are present in the observation region. Each of the observation regions may be the entire field of view of SEM, or a certain region in the field of view.

As described in the previous patent application by the present applicant (Japanese Patent Application Laid-Open (kokai) No. 2005-206784), when cells are observed in a cross section, and cells satisfying the requirement represented by the below-described relation (A) or (B) account for 50% of all cells in the cross section, the cells are regarded as being in a true spherical form. However, this is insufficient to indicate that the cells are in a true spherical form, since the cells are observed in only one cross section. The requirement represented by the below-described relation (B) corresponds to the aspect ratio employed in the present invention, and “0.5” shown in relation (B) corresponds to an aspect ratio of 1.5. In the present invention, cells are observed in two orthogonal cross sections, and cells satisfying more stringent requirements than the requirements represented by these relations are regarded as being in a true spherical form.
(A): 0≦(m−n)/m≦0.5
(B): 0≦(m−n)/n≦0.5
(wherein m represents the length of major axis of a cell, and n represents the length of minor axis of the cell).

Also, the elastomer porous material of the present invention can be confirmed to have substantially true spherical cells by determining that, in each of the first and second observation regions, cells having a shape factor SF1—which indicates the roundness of a circle and is represented by the following formula in terms of the length of major axis a of each cell and the area A thereof—of 150 or less account for 80% or more of all cells.

SF 1 = π a 2 4 A × 100 [ F7 ]

Furthermore, the elastomer porous material of the present invention can be confirmed to have substantially true spherical cells having smooth circumferential surfaces with no irregularities by determining that, in the first or second observation region, cells having a shape factor SF2—which indicates the remoteness from complete roundness and is represented by the following formula in terms of the area A of each cell and the perimeter length P thereof—of 130 or less account for 80% or more of all cells.

SF 2 = P 2 4 π A × 100 [ F8 ]

When the aforementioned requirement (in relation to the shape factor SF2) is satisfied in any one of the first and second observation regions, it is enough to confirm that the elastomer porous material of the present invention has the aforementioned cells. However, the requirement may be satisfied in both the first and second observation regions.

Similar to the case of the aspect ratio, the shape factor SF1 or SF2 may be determined through analysis of SEM image data input into a computer by means of, for example, image analysis software.

In the entirety of the elastomer porous material of the present invention, cells of uniform size are distributed uniformly. Therefore, observation of any cross section of the porous material provides results similar to those as described above.

The elastomer porous material of the present invention has numerous very fine cells which are densely distributed. Therefore, the number of cells per unit area in the elastomer porous material greatly differs from that in a conventional porous material produced through, for example, chemical foaming and having a porosity comparable to that of the elastomer porous material. The elastomer porous material of the present invention exhibits a porosity of, for example, 30% or more, preferably 40% or more. In the elastomer porous material, the number of cells per mm2 is 200 or more, preferably 1,000 or more, more preferably 2,000 or more.

Next will be described the elastomer porous material of the present invention and a production method therefor by taking, as an example, the case of a silicone elastomer porous material.

The silicone elastomer porous material may be basically produced from a water-in-oil emulsion which contains a liquid silicone rubber material that forms a silicone elastomer through curing, and contains, as a dispersion phase, water or a mixture of water and an aqueous solvent (e.g., alcohol). In this case, the liquid silicone rubber material (preferably, a liquid silicone rubber material having low viscosity) and water may be thoroughly stirred under reduced pressure to form an emulsion, which may be immediately followed by heating for curing.

The silicone elastomer porous material of the present invention may be suitably produced from a water-in-oil emulsion which contains a liquid silicone rubber material that forms a silicone elastomer through curing, water, and a silicone oil material having interfacial activity, and which is produced under reduced pressure.

No particular limitation is imposed on the liquid silicone rubber material, so long as it forms a silicone elastomer through curing under heating. However, the liquid silicone rubber material employed is preferably a so-called addition-reaction-curable liquid silicone rubber material.

As described above, the elastomer porous material of the present invention has substantially true spherical cells. For production of the elastomer porous material, an emulsion composition must be prepared under reduced pressure. As used herein, “preparation of an emulsion composition under reduced pressure” refers to the case where a process of preparing an emulsion through mixing and stirring of raw materials is carried out under reduced pressure. Thus, even when an emulsion composition prepared at ambient pressure is subjected to degassing under reduced pressure, satisfactory effects are not obtained.

In the present invention, the liquid silicone rubber material employed may be a commercially available one. For example, in the case of a commercially available addition-reaction-curable liquid silicone rubber material, an unsaturated-aliphatic-group-containing polysiloxane and an active-hydrogen-containing polysiloxane—which form the silicone rubber material—are provided in separate packages, and a curing catalyst required for curing both the polysiloxanes, which will be described in detail hereinbelow, is included in the unsaturated-aliphatic-group-containing polysiloxane package. Needless to say, two or more liquid silicone rubber materials may be employed in combination.

The silicone oil material having interfacial activity serves as a dispersion stabilizer for stably dispersing water in an emulsion. Thus, the silicone oil material having interfacial activity exhibits affinity for both water and the liquid silicone rubber material.

Needless to say, in the aforementioned water-in-oil emulsion, water is dispersed in the form of particles (droplets) as a discontinuous phase (dispersed phase). As described in detail hereinbelow, the diameter of water particles substantially determines the diameter of cells (pores) of the silicone elastomer porous material of the present invention.

From the viewpoint of production of a water-in-oil emulsion exhibiting particularly excellent water dispersion stability, preferably, the silicone oil material having interfacial activity and water are employed in amounts of 0.2 to 10 parts by weight and 10 to 250 parts by weight, respectively, on the basis of 100 parts by weight of the liquid silicone rubber material. When such an emulsion exhibiting excellent water dispersion stability is employed, a good porous material can be further reliably produced. Needless to say, two or more silicone oil materials having interfacial activity may be employed in combination.

When a liquid rubber material other than silicone is employed, the emulsion composition may be an emulsion containing, as a continuous phase, the liquid rubber material and, as a dispersed phase, a solvent which can be phase-separated from the continuous phase, and optionally containing a surfactant or a substance having interfacial activity.

The elastomer porous material of the present invention may contain, in consideration of the intended use thereof, a variety of additives. Examples of such an additive include a colorant (e.g., a pigment or a dye), a conductivity-imparting material (e.g., carbon black or metal powder), and a filler (e.g., silica).

The emulsion composition employed in the present invention may be produced through various methods. For example, a water-in-oil emulsion composition containing a silicone elastomer may be generally produced by mixing a liquid silicone rubber material, a silicone oil material having interfacial activity, and water, and optionally an additive under reduced pressure, and by thoroughly stirring the resultant mixture. For preparation of the emulsion composition, no particular limitation is imposed on the order of addition of the respective materials, as well as the method for mixing the materials, and the respective materials may be added sequentially, or mixtures each containing a plurality of materials may be mixed together.

As used herein, “reduced pressure” refers to, for example, −30 kPa or less, preferably −60 kPa or less (lower limit: about −100 kPa).

Instead of mixing/stirring under reduced pressure, the respective raw materials may be degassed in advance, and then the materials may be stirred so that they are not exposed to a gas (e.g., air), to thereby prepare an emulsion.

For production of the elastomer porous material from the emulsion composition, the emulsion composition is subjected to primary heating (for curing) in the presence of an optional curing catalyst so that components of the composition are not evaporated, and subsequently the resultant composition is subjected to secondary heating for liquid removal and complete curing.

For production of the silicone elastomer porous material, firstly, the emulsion composition is subjected to primary heating. The primary heating is preferably carried out at 130° C. or lower for heating and curing the liquid silicone rubber material without evaporation of water contained in the emulsion composition. The primary heating temperature is generally 80° C. or higher, and the heating time is generally about 5 minutes to about 60 minutes. Through this primary heating, the liquid silicone rubber material is cured, and water particles remain in the cured rubber material in the form of being dispersed in the emulsion. The silicone rubber material is cured to such an extent that it can resist expansion force upon evaporation of water by secondary heating described below. Secondary heating is carried out for removing water from the cured silicone rubber material containing water particles. The secondary heating is preferably carried out at 70° C. to 300° C. When the heating temperature is lower than 70° C., removal of water requires a long period of time, whereas when the heating temperature exceeds 300° C., the cured silicone rubber material may be impaired. When the heating temperature is 70° C. to 300° C., removal of water (through evaporation) is completed by heating for 1 to 24 hours. Through this secondary heating, water is evaporated and removed, and eventual curing of the silicone rubber material is achieved. After removal of water through evaporation, cells having a diameter almost equal to that of water particles are formed in the cured silicone rubber material (silicone elastomer).

Thus, the elastomer porous material of the present invention can be produced from the emulsion composition without involving foaming action (e.g., chemical foaming). The dispersed phase (e.g., water particles) contained in the emulsion composition remains in the elastomer cured through the primary heating, and only evaporates upon the secondary heating.

The silicone elastomer porous material of the present invention can be employed in a variety of fields. For example, the porous material can be employed in components of image-forming devices (e.g., copying machines and laser printers), including a developing roller, a toner-feeding roller, a transfer roller, and a cleaning roller. Also, the silicone elastomer porous material can be employed in paper-sheet-feeding rollers of copying machines, various types of printers, and plotters, as well as in fixing components (e.g., a fixing roller and a pressure roller). All of these rollers have basically the same structure, in which an elastic layer formed of the silicone elastomer porous material of the present invention is provided around a core bar. The thickness of the elastic layer, which may vary depending on the type of the roller, is generally about 0.1 mm to about 15 mm, and the length of the elastic layer is generally up to 400 mm. The outer diameter of the core bar, which may also vary depending on the type of the roller, is generally about 5 mm to about 50 mm.

EXAMPLES Example 1

As described below, a water-in-oil emulsion composition was prepared by carrying out mixing and stirring under reduced pressure (−98 kPa) in a reduced-pressure stirring apparatus.

A filler (5 parts by weight) and a silicone oil having interfacial activity (5 parts by weight) were added to and mixed with liquid silicone rubber (trade name: DY35-7002, obtained from Dow Corning Toray Co., Ltd.) (100 parts by weight) serving as a liquid silicone rubber material, and the mixture was stirred. Subsequently, water (140 parts by weight) was gradually added to the resultant mixture under stirring, to thereby prepare a water-in-oil emulsion composition.

The resultant emulsion was added to a die containing an iron core bar having a length of a surface on which rubber is applied (hereinafter may be referred to as a “rubber surface length”) of 310 mm and an outer diameter φ of 20 mm, and heating (primary heating) was carried out at 130° C. for 40 minutes, to thereby form a molded product. The molded product (porous material precursor) was subjected to heating (secondary heating) in an electric furnace at 200° C. for six hours, to thereby remove water. Thereafter, polishing was carried out, to thereby produce a roller having an outer diameter φ of 35 mm and a hardness (Asker C) of 40°.

Example 2

As described below, a water-in-oil emulsion composition was prepared by carrying out mixing and stirring under reduced pressure (−60 kPa) in a reduced-pressure stirring apparatus.

A filler (5 parts by weight) and a silicone oil having interfacial activity (5 parts by weight) were added to and mixed with liquid silicone rubber (trade name: DY35-7002, obtained from Dow Corning Toray Co., Ltd.) (100 parts by weight) serving as a liquid silicone rubber material, and the mixture was stirred. Subsequently, water (140 parts by weight) was gradually added to the resultant mixture under stirring, to thereby prepare a water-in-oil emulsion composition.

Subsequent processes were carried out in a manner similar to that of Example 1, to thereby produce a roller having an outer diameter φ of 35 mm and a hardness (Asker C) of 40°.

Example 3

As described below, a water-in-oil emulsion composition was prepared by carrying out mixing and stirring under reduced pressure (−30 kPa) in a reduced-pressure stirring apparatus.

A filler (5 parts by weight) and a silicone oil having interfacial activity (5 parts by weight) were added to and mixed with liquid silicone rubber (trade name: DY35-7002, obtained from Dow Corning Toray Co., Ltd.) (100 parts by weight) serving as a liquid silicone rubber material, and the mixture was stirred under reduced pressure (−30 kPa). Subsequently, water (140 parts by weight) was gradually added to the resultant mixture under stirring, to thereby prepare a water-in-oil emulsion composition.

Subsequent processes were carried out in a manner similar to that of Example 1, to thereby produce a roller having an outer diameter φ of 35 mm and a hardness (Asker C) of 40°.

Comparative Example 1

In Comparative Example 1, a roller having an outer diameter φ of 35 mm and a hardness (Asker C) of 40° was produced from a silicone elastomer porous material (produced by kneading Silicone Rubber KE-951U (product of Shin-Etsu Chemical Co., Ltd.) with a vulcanizing agent compatible therewith and a chemical foaming agent, followed by foaming).

Comparative Example 2

A filler (5 parts by weight) and a silicone oil having interfacial activity (5 parts by weight) were mixed with liquid silicone rubber (trade name: DY35-7002, obtained from Dow Corning Toray Co., Ltd.) (100 parts by weight) serving as a liquid silicone rubber material, and the mixture was stirred by means of a hand mixer. Subsequently, water (140 parts by weight) was gradually added to the resultant mixture under stirring, to thereby prepare a water-in-oil emulsion composition.

The resultant emulsion was defoamed in a pressure reducer, to thereby remove air contained in the emulsion. Subsequently, the emulsion was added to a die containing an iron core bar having a rubber surface length of 310 mm and an outer diameter of 20 mm, and heating (primary heating) was carried out at 130° C. for 40 minutes, to thereby form a molded product. The molded product (porous material precursor) was subjected to heating (secondary heating) in an electric furnace at 200° C. for six hours, to thereby remove water. Thereafter, polishing was carried out, to thereby produce a roller having an outer diameter φ of 35 mm and a hardness (Acker C) of 20°.

Comparative Example 3

As described below, a water-in-oil emulsion composition was prepared by carrying out mixing and stirring under reduced pressure (−20 kPa) in a reduced-pressure stirring apparatus.

A filler (5 parts by weight) and a silicone oil having interfacial activity (5 parts by weight) were added to and mixed with liquid silicone rubber (trade name: DY35-7002, obtained from Dow Corning Toray Co., Ltd.) (100 parts by weight) serving as a liquid silicone rubber material, and the mixture was stirred. Subsequently, water (140 parts by weight) was gradually added to the resultant mixture under stirring, to thereby prepare a water-in-oil emulsion composition.

Subsequent processes were carried out in a manner similar to that of Comparative Example 2, to thereby produce a roller having an outer diameter φ of 35 mm and a hardness (Asker C) of 40°.

Test Example 1

Each of the rollers of Examples 1 to 3 and Comparative Examples 1 to 3 was cut, in the vicinity of the center in an axial direction, in a radial direction and in a longitudinal direction orthogonal thereto. Each of the resultant cross sections was observed under an electron microscope (JSM 5600, product of JEOL Ltd.), and an image of the cross section including 40 to 80 cells was obtained (magnification: ×1,000 for Examples, ×100 for Comparative Examples). A certain rectangular region including cells whose entirety can be observed was determined in each of the cross-sectional images (a first observation region for the radial cross-sectional image and a second observation region for the longitudinal cross-sectional image). Cells included in the rectangular region (all cells on the boundary line were included in the region) were subjected to the below-described measurements. In this test, the first observation region was determined in the radial cross section, and the second observation region was determined in the longitudinal cross section. However, the first and second observation regions are not limited thereto, and may be determined in any orthogonal cross sections.

FIGS. 1 to 12 show SEM photographs of radial cross sections and first observation regions thereof, and SEM photographs of longitudinal cross sections and second observation regions thereof in Examples 1 to 3 and Comparative Examples 1 to 3.

The data of each cross-sectional image were input into Macrosoft lenaraf 200 operated in Microsoft Excel. A reference length was determined, and the circumference of each cell included in each observation region was traced, to thereby select points corresponding the contour of the cell. Aspect ratio, SF1, and SF2 were calculated through the below-described methods. The results are shown in Table 1.

<Aspect Ratio>

For each cell, about 20 points were chosen on the perimeter thereof. On the basis of the thus-chosen points, the maximum diameter of each cell (length of major axis) a and the length b of minor axis orthogonal thereto were determined, to thereby calculate the aspect ratio a/b of the cell.

<SF1>

For each cell, about 20 points were chosen on the perimeter thereof. On the basis of the thus-chosen points, the maximum diameter of each cell (length of major axis) a was determined, and the area of the cell was determined by means of the software. SF1 was calculated from the thus-determined values. FIGS. 13 to 24 show histograms of SF1 in Examples 1 to 3 and Comparative Examples 1 to 3.

<SF2>

For each cell, about 20 points were chosen on the perimeter thereof. On the basis of the thus-chosen points, the perimeter length and area of the cell were determined by means of the software. SF2 was calculated from the thus-determined values. FIGS. 25 to 36 show histograms of SF2 in Examples 1 to 3 and Comparative Examples 1 to 3.

Test Example 2

Each of the cross-sectional images obtained in Test Example 1 was printed out, and the inside of each cell included in the first and second observation regions was painted with a black marker pen. The thus-painted image was scanned with a scanner, and the diameter and number of cells were determined by means of V10 for Windows (registered trademark) 95 (product of Toyobo Co., Ltd.). Definition was adjusted to 150 so that cells were well recognized by the software. Porosity was calculated on the basis of the ratio of the area of cells (average cell diameter×the number of cells) to that of the image. The number of cells per mm2 was calculated by dividing the number of cells in the observation region by the area of the observation region. The results are shown in Table 1.

TABLE 1 Example 1 Example 2 Example 3 First Second First Second First Second observation observation observation observation observation observation region region region region region region Number of cells counted 47 63 45 40 74 43 Aspect ratio Mean 1.16 1.16 1.22 1.27 1.26 1.21 Cells of 1.3 or less [%] 89 87 80 70 72 84 Cells of 1.2 or less [%] 77 73 60 44 50 63 Cells of 1.1 or less [%] 36 37 33 23 22 35 SF1 Mean 121.82 119.72 139.18 141.16 138.11 131.87 Cells of 150 or less [%] 94 90 83 80 81 85 Cells of 140 or less [%] 87 86 64 64 70 79 Cells of 130 or less [%] 77 78 51 54 55 65 SF2 Mean 109.27 106.84 120.48 122.12 115.06 116.53 Cells of 130 or less [%] 94 98 80 82 85 81 Cells of 120 or less [%] 87 97 56 56 74 72 Cells of 110 or less [%] 70 81 40 41 50 44 Cell diameter Mean [μm] 10 9 Cells of 50 μm or less [%] 100 100 Cells of 30 μm or less [%] 100 99 Cells of 20 μm or less [%] 94 97 Cells of 15 μm or less [%] 79 88 Cells of 10 μm or less [%] 56 65 Number of cells/mm2 4884 6035 Porosity [%] 37 34 Comparative Comparative Comparative Example 1 Example 2 Example 3 First Second First Second First Second observation observation observation observation observation observation region region region region region region Number of cells counted 44 74 55 54 51 61 Aspect ratio Mean 1.8 1.57 1.27 1.26 1.29 1.32 Cells of 1.3 or less [%] 5 30 62 67 63 66 Cells of 1.2 or less [%] 5 18 40 50 37 41 Cells of 1.1 or less [%] 2 8 16 19 20 15 SF1 Mean 201.04 177.77 144.89 143.26 147.94 148.43 Cells of 150 or less [%] 20 31 64 69 69 69 Cells of 140 or less [%] 9 23 47 56 47 59 Cells of 130 or less [%] 5 18 38 37 37 48 SF2 Mean 132.54 130.37 122.30 123.98 122.89 123.25 Cells of 130 or less [%] 61 58 75 74 76 72 Cells of 120 or less [%] 36 39 62 57 61 61 Cells of 110 or less [%] 14 8 35 22 31 31 Cell diameter Mean [μm] 193 160 Cells of 50 μm or less [%] 0 0 Cells of 30 μm or less [%] 0 0 Cells of 20 μm or less [%] 0 0 Cells of 15 μm or less [%] 0 0 Cells of 10 μm or less [%] 0 0 Number of cells/mm2 16 22 Porosity [%] 47 44

(Summary of the Results)

In the case of the roller of Example 1, in each of the first and second observation regions, cell diameter was normally distributed around the mean value (about 10 μm), and the amount of cells having an aspect ratio of 1.3 or less was found to be 87% or more. As shown in FIGS. 13 and 14, in the case of the roller of Example 1, virtually no difference was observed in shape factor SF1 between cells of the first observation region and those of the second observation region, and, in each of the observation regions, most cells exhibited an SF1 of 130 or less; specifically, an SF1 falling within a narrow range around 120 (mean value). Thus, the roller of Example 1 was found to have substantially true spherical cells. In addition, as shown in FIGS. 25 and 26, in each of the observation regions, most cells exhibited an SF2 (indicating to the remoteness from complete roundness; i.e., circumferential irregularities) falling within a narrow range of 130 or less.

Also, in the case of the roller of Example 2 or 3, in each of the first and second observation regions, cell diameter was normally distributed around the mean value (about 10 μm), and the amount of cells having an aspect ratio of 1.3 or less was found to be 70% or more. As shown in FIGS. 15 to 18, in the case of the roller of Example 2 or 3, virtually no difference was observed in shape factor SF1 between cells of the first observation region and those of the second observation region, and, in each of the observation regions, 80% or more of all cells exhibited an SF1 falling within a narrow range of 150 or less. Thus, the roller of Example 2 or 3 was found to have substantially true spherical cells. In addition, as shown in FIGS. 27 to 30, in each of the observation regions, 80% or more of all cells exhibited an SF2 (indicating to the remoteness from complete roundness; i.e., circumferential irregularities) of 130 or less.

In contrast, in the case of the roller of Comparative Example 1, the amount of cells having an aspect ratio of 1.3 or less was found to be small; i.e., large amounts of cells were found to be in a flattened spherical form. As shown in FIGS. 19 and 20, in the case of the roller of Comparative Example 1, considerably large amounts of cells exhibited high SF1, and cells of different SF1 values were distributed in each of the first and second observation regions. Thus, the roller of Comparative Example 1 was found to have non-uniform and considerably flattened cells. In addition, as shown in FIGS. 31 and 32, in the case of the roller of Comparative Example 1, cells of different shape factor SF2 values were distributed in each of the observation regions, and large amounts of cells exhibited high SF2, as compared with the cases of Examples 1 to 3. Thus, the roller of Comparative Example 1 was also found to have non-uniform and distorted spherical cells.

In the case of the roller of Comparative Example 2 or 3, the amount of cells having an aspect ratio of 1.3 or less was found to be small (62 to 67%); i.e., the amount of cells having a flattened spherical form was found to be large, as compared with the cases of Examples 1 to 3. As shown in FIGS. 21 to 24, in the case of the roller of Comparative Example 2 or 3, large amounts of cells exhibited high SF1 (i.e., 60 to 70% of all cells exhibited an SF1 of 150 or less), and cells of different SF1 values were distributed in each of the first and second observation regions. Thus, the roller of Comparative Example 2 or 3 was found to have non-uniform and considerably flattened cells. In addition, as shown in FIGS. 33 to 36, in the case of the roller of Comparative Example 2 or 3, cells of different shape factor SF2 values were distributed in each of the observation regions, and large amounts of cells exhibited high SF2 (i.e., 70 to 80% of all cells exhibited an SF2 of 130 or less), as compared with the cases of Examples 1 to 3. Thus, the roller of Comparative Example 2 or 3 was also found to have non-uniform and distorted spherical cells.

In the roller of Example 1, the amount of cells having a diameter of 50 μm or less was found to be 100%, and the number of cells/mm2 was found to be 4,884 or more. In contrast, in the roller of Comparative Example 1, the amount of cells having a diameter of 50 μm or less was found to be 0%, and the number of cells/mm2 was found to be 22 or less. These data indicate that, in the roller of Example 1, very fine cells are densely distributed, as compared with the roller of Comparative Example 1.

Test Example 3

A durability test was carried out by using a belt fixing apparatus 10 as shown in FIG. 37, which includes a fixing roller 21, a pressure roller 22, a heating roller 23, and a fixing belt 25. In the belt fixing apparatus 10, the fixing roller 21 is rotatably supported by a shaft; the pressure roller 22 is rotatably supported below the roller 21 so that the roller 22 abuts the roller 21; and the heating roller 23 is rotatably supported generally above the roller 21. A heat source 24 is provided in the interior of the heating roller 23, and the fixing belt (endless heat transfer belt) 25 is wound around the heating roller 23 and the fixing roller 21.

Each of the rollers of Examples 1 to 3 and Comparative Examples 1 to 3 was applied, as the fixing roller, to the belt fixing apparatus 10, and the time elapsed until the fixing roller was broken was measured. There was employed, as the pressure roller 22, a roller prepared by covering a silicone sponge (φ: 35 mm, thickness: 2.5 mm, hardness (Asker C): 68°) with a PFA tube (thickness: 30 μm). The nip width was adjusted to 10.5 to 11.5 mm. The durability test was carried out under the following conditions: belt surface (heated to 160 to 170° C.), and continuous operation (8 hours/day under heating, and 16 hours/day with turning off the heat source (heater)). For each type of roller, the durability test was carried out five times. Upon the durability test, the warm-up time of each roller was measured, and the ratio of the warm-up time of the roller to that of the roller of Comparative Example 1 was determined. As used herein, “warm-up time” refers to the rise time in a standby state. The results are shown in Table 2.

TABLE 2 Comp. Comp. Comp. Ex. 1 Ex. 2 Ex. 3 Ex. 1 Ex. 2 Ex. 3 Warm-up Average of five 1.01 1.01 1.01 1 1.01 1.01 time ratio measurements Endurance 1 576 623 506 120 360 325 time 2 624 594 516 96 384 358 3 528 542 555 48 408 316 4 572 528 574 48 432 371 5 534 556 522 24 228 321

(Summary of the Results)

As shown in Table 2, the warm-up time of each of the rollers of Examples 1 to 3 and Comparative Examples 2 and 3 was almost equal to that of the roller of Comparative Example 1. These data indicate that the rollers of Examples 1 to 3 exhibit heat insulation property comparable to that of a conventional sponge roller.

As is clear from Table 2, each of the rollers of Examples 1 to 3 can be continuously operated for 500 hours or longer, and, in contrast, the roller of Comparative Example 1 may be generally broken through operation for 100 hours or shorter, and the roller of Comparative Example 2 or 3 may be broken through operation for about 300 hours. These data indicate that the rollers of Examples 1 to 3 exhibit durability higher than that of the rollers of Comparative Examples 1 to 3 (i.e., conventional rollers).

Claims

1. An elastomer porous material, wherein:

when cells in a first observation region of a first cross section are observed at a certain magnification, cells having an aspect ratio a/b of 1.3 or less account for 70% or more of all cells in the first observation region, wherein a represents a maximum diameter of each cell and b represents a length of a minor axis of that cell as measured in a direction orthogonal thereto, and
when cells in a second observation region of a second cross section orthogonal to the first cross section are observed at said certain magnification, cells having an aspect ratio a/b of 1.3 or less account for 70% or more of all cells in the second observation region, wherein a represents a maximum diameter of each cell and b represents a length of a minor axis of that cell as measured in a direction orthogonal thereto.

2. The elastomer porous material according to claim 1, which is produced from an emulsion composition comprising, as a continuous phase, a liquid rubber material which forms an elastomer through curing.

3. The elastomer porous material according to claim 2, wherein the liquid rubber material is a liquid silicone rubber material.

4. The elastomer porous material according to claim 1, wherein, in the first or second observation region, cells having a diameter of 50 μm or less account for 50% or more of all cells.

5. The elastomer porous material according to claim 1, wherein, in each of the first and second observation regions, cells having a shape factor SF1 of 150 or less account for 80% or more of all cells, wherein SF1 indicates roundness of a circle and is represented by formula F1: SF ⁢ ⁢ 1 = π ⁢ ⁢ a 2 4 ⁢ ⁢ A × 100,

wherein a represents a length of a major axis of each cell, and A represents an area thereof.

6. The elastomer porous material according to claim 1, wherein, in the first observation region, cells having a shape factor SF2 of 130 or less account for 80% or more of all cells, wherein SF2 indicates remoteness from complete roundness and is represented by formula F2: SF ⁢ ⁢ 2 = P 2 4 ⁢ π ⁢ ⁢ A × 100,

wherein A represents an area of each cell, and P represents a perimeter length thereof.

7. The elastomer porous material according to claim 1, wherein, in the second observation region, cells having a shape factor SF2 of 130 or less account for 80% or more of all cells, wherein SF2 indicates remoteness from complete roundness and is represented by formula F3: SF ⁢ ⁢ 2 = P 2 4 ⁢ π ⁢ ⁢ A × 100,

wherein A represents an area of each cell, and P represents a perimeter length thereof.

8. The elastomer porous material according to claim 1, which exhibits a porosity of 30% or more and has 200 or more cells per mm2 as observed in a cross section.

9. A roll member comprising the elastomer porous material as recited in claim 1.

10. A fixing member comprising the elastomer porous material as recited in claim 1.

11. A method for producing an elastomer porous material, comprising:

preparing, under reduced pressure, an emulsion composition comprising, as a continuous phase, a liquid rubber material which forms an elastomer through curing; and
curing the emulsion composition while removing a dispersion phase, to thereby produce the elastomer porous material.

12. The method for producing an elastomer porous material according to claim 1, wherein the liquid rubber material is a liquid silicone rubber material.

13. The method for producing an elastomer porous material according to claim 1, wherein the emulsion composition is a water-in-oil emulsion composition comprising a liquid silicone rubber material, a silicone oil material having interfacial activity, and water.

14. The method for producing an elastomer porous material according to claim 11, wherein:

when cells in a first observation region of a first cross section are observed at a certain magnification, cells having an aspect ratio a/b of 1.3 or less account for 70% or more of all cells in the first observation region, wherein a represents a maximum diameter of each cell and b represents a length of a minor axis of that cell as measured in a direction orthogonal thereto, and
when cells in a second observation region of a second cross section orthogonal to the first cross section are observed at said certain magnification, cells having an aspect ratio a/b of 1.3 or less account for 70% or more of all cells in the second observation region, wherein a represents a maximum diameter of each cell and b represents a length of a minor axis of that cell as measured in a direction orthogonal thereto.

15. The method for producing an elastomer porous material according to claim 11, wherein, in the first or second observation region, cells having a diameter of 50 μm or less account for 50% or more of all cells.

16. The method for producing an elastomer porous material according to claim 11, wherein, in each of the first and second observation regions, cells having a shape factor SF1 of 150 or less account for 80% or more of all cells, wherein SF1 indicates roundness of a circle and is represented by following formula F4: SF ⁢ ⁢ 1 = π ⁢ ⁢ a 2 4 ⁢ ⁢ A × 100,

wherein a represents a length of a major axis of each cell, and A represents an area thereof.

17. The method for producing an elastomer porous material according to claim 11, wherein, in the first observation region, cells having a shape factor SF2 of 130 or less account for 80% or more of all cells, wherein SF2 indicates remoteness from complete roundness and is represented by formula F5: SF ⁢ ⁢ 2 = P 2 4 ⁢ π ⁢ ⁢ A × 100,

wherein A represents an area of each cell, and P represents a perimeter length thereof.

18. The method for producing an elastomer porous material according to claim 11, wherein, in the second observation region, cells having a shape factor SF2 of 130 or less account for 80% or more of all cells, wherein SF2 indicates remoteness from complete roundness and is represented by formula F6: SF ⁢ ⁢ 2 = P 2 4 ⁢ π ⁢ ⁢ A × 100,

wherein A represents an area each cell, and P represents a perimeter length thereof.
Referenced Cited
U.S. Patent Documents
20100272989 October 28, 2010 Nemoto et al.
20100305225 December 2, 2010 Nemoto et al.
Foreign Patent Documents
06-287348 October 1994 JP
10-025374 January 1998 JP
2000-296668 October 2000 JP
2004-143332 May 2004 JP
2005-206784 August 2005 JP
2006-052262 February 2006 JP
2006-308716 November 2006 JP
Other references
  • International Search Report—PCT/JP2008/071826—Feb. 3, 20009.
Patent History
Patent number: 8222309
Type: Grant
Filed: Dec 1, 2008
Date of Patent: Jul 17, 2012
Patent Publication Number: 20100311851
Assignee: Synztec Co, Ltd. (Tokyo)
Inventors: Wataru Nemoto (Tokyo), Kazuya Takato (Tokyo), Asuka Koyanagi (Tokyo), Jun Ogawa (Tokyo), Atsushi Ikeda (Tokyo)
Primary Examiner: Randy Gulakowski
Assistant Examiner: Kara Boyle
Attorney: Young & Thompson
Application Number: 12/745,576